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Optimized method for rapid electroblotting Protein electroblotting is a common method for transferring out of a polyacrylamide gel onto a membrane for subsequent western blotting. With a high-current power supply, such as that found in the Thermo Scientific™ Pierce™ G2 Fast Blotter, and a high–ionic strength transfer buffer, protein transfer from nitrocellulose or polyvinylidene difluoride (PVDF) membranes can be achieved in 5–10 m, even with proteins as large as 300 kDa.

Introduction Western blotting is a commonly used technique for detection of proteins. The quality of data derived from western blotting is dependent on several factors, including the sample integrity, blocking buffer, quality, antibody concentration, type of membrane and technique. One of the most critical factors for satisfactory results is consistent and efficient transfer of the proteins from the gel to the membrane. Traditional transfer techniques include tank and semidry transfers. The Pierce™ G2 Fast Blotter (Fig. 1) represents a semidry transfer method. Tank transfer is often considered the optimal method for electroblotting because it is very reproducible and generally provides good transfer efficiency. In tank transfer, the transfer sandwich is secured in a cassette and submerged in a tank of transfer buffer. This method uses a large volume of buffer containing methanol and © 2013 Nature America, Inc. All rights reserved. America, Inc. © 2013 Nature is usually performed with an ice pack within the transfer tank or by Figure 1 | The Thermo Scientific™ Pierce™ G2 Fast Blotter can transfer proteins placing the whole apparatus in a cold room to offset the heat that is from gel to membrane in 10 m.

npg generated. Tank transfer takes a minimum of 2h and longer for larger proteins. With semidry transfer, the gel and membrane are sandwiched Protein transfer using the Pierce™ G2 Fast Blotter versus between two pieces of filter paper that have been saturated in transfer traditional tank method buffer. This method has become quite popular because it uses less HeLa lysate (~3.0 mg/mL) prepared by nitrogen cavitation was serially buffer and generally requires less time (only 30–60 m). The efficiency diluted 1:2, prepared for SDS-PAGE and separated on gels according to of semidry transfer is generally perceived as inferior to tank methods, suppliers’ recommendations. The proteins were then transferred from especially with respect to the transfer of high–molecular weight gel to membrane using various techniques. proteins. For electroblotting with the Pierce™ G2 Fast Blotter, the gels, filter Rapid protein electroblotting, a more recent technique, uses a paper pre-wetted with Thermo Scientific™ Pierce™ 1-Step Transfer high–ionic strength transfer buffer in combination with a high-current Buffer and membranes were assembled in the Pierce™ G2 Fast Blotter power supply that greatly increases the rate of protein migration from Cassette as directed. The cassette was placed into the Pierce™ G2 Fast gel to membrane. By increasing the current 10-fold or more across Blotter Control Unit (Fig. 2), and proteins were transferred using the the surface of the sandwich, transfer efficiency equivalent to tank and ‘High MW’ preprogrammed method for 1 minigel (1.3 amps constant, semidry methods can be attained in as little as 5–10 m. 25 volts limit, 10 m). For traditional overnight tank transfer, the gels, filter paper and Greg Kilmer, Brian Webb, Boguslawa R Dworecki, membrane were equilibrated in cold Towbin buffer1 (25 mM Tris, Eric Hommema, Steve Shiflett & Priya Rangaraj 192 mM glycine, 20% methanol) for 15 m. The transfer sandwich was assembled in a commercially available tank, and 30 volts constant was Thermo Fisher Scientific, Rockford, Illinois, USA. Correspondence should be addressed to P.R. ([email protected]) or B.W. ([email protected]). applied for 16 h at 4 °C.

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Conclusion The Pierce™ G2 Fast Blotter in combination with Pierce™ 1-Step Transfer Buffer provides highly efficient transfer of low–, medium– and high–molecular weight proteins from polyacrylamide gels to nitrocellulose or PVDF membranes in just 10 m. The transfer efficiency is equivalent to or better than that for traditional Western blotting transfer methods (Fig. 3). Of particular interest are the efficient 10-m transfers of mTOR and Ecm29, high–molecular weight proteins of approximately 298 kDa and 205 kDa, respectively, by the Pierce™ G2 Fast Blotter. Generally, high–molecular weight proteins are hard to transfer even using traditional tank methods. We have found that proteins up to 300 kDa transfer well in 10 m using the Pierce™ G2 Fast Blotter and the Pierce™ 1-Step Transfer Buffer (data not shown).

Figure 2 | The Pierce™ G2 Blotter cassette, which contains the gel, blotting membrane and filter paper, inserts easily into the power supply. The transfer Molecular Low Mid High High conditions are then selected using the touchscreen panel on the unit. weight range (<25 kDa) (25-150 kDa) (>150 kDa) (>150 kDa) Target protein Cyclophilin B PLK-1 Ecm29 mTOR and size (21 kDa) (67 kDa) (250 kDa) (289 kDa) Immunodetection Pierce™ G2 Fast Blotter 10 m Resulting membranes from the two transfer methods were cut into Conventional tank Overnight thirds. The top sections were probed with either Thermo Scientific™

anti-mTOR Antibody (Product #PA1-518) or Thermo Scientific™ anti- Figure 3 | Western blot comparison of low–, medium– and high–molecular Ecm29 Antibody (Product #PA3-035). The middle sections were probed weight proteins transferred to nitrocellulose membrane using various transfer with Thermo Scientific™ anti-PLK1 Antibody (Product #MA1-848), techniques. The Thermo Scientific™ Pierce™ G2 Fast Blotter rapidly transfers a wide range of molecular weight proteins to membrane with similar or better whereas the bottom parts were probed with Thermo Scientific™ anti– efficiency than traditional transfer methods, such as tank and semidry, as well Cyclophilin B Antibody (Product #PA1-027A). were diluted as other rapid blotting systems. Experiment details can be found at http:// thermoscientific.com/g2blotter in Thermo Scientific™ Pierce Fast Blocking Buffer (Product #37575). The membranes were then processed using Thermo Scientific™

Pierce™ Fast Western Blot Kits, SuperSignal™ West Dura Kits (Product 1. Towbin, H., Staehelin, T. & Gordon, J. Electrophoretic transfer of proteins from #35075 (Mouse) and #35076 (Rabbit)). The resulting blots were then polyacrylamide gels to nitrocellulose sheets: procedure and some applications. Proc. Natl. Acad. Sci. USA 76, 4350–4354 (1979). simultaneously imaged using the Thermo Scientific™ MYECL™ Imager © 2013 Nature America, Inc. All rights reserved. America, Inc. © 2013 Nature (Product #62236). npg

This article was submitted to Nature Methods by a commercial organization and has not been peer reviewed. Nature Methods takes no responsibility for the accuracy or otherwise of the information provided.

ii | OCTOBER 2013 | nature methods